enzymes as green catalysts for … eve… · enzymes as green catalysts for pharmacuetical industry...
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guide
Profitable:
- 2 Bn USD in sales
- 7-8% organic growth
R&D intensive:
~7,000 patents,
~14% of sales spent on R&D
Global:
+6,000 employees,
700 products in 140 countries
Sustainable: industry leader of the
biotechnology sector in the Dow
Jones World for 12 yrs in a row and
SAM Gold Class ranking
Household
Care
Food &
Beverages Bioenergy
Agriculture
& Feed
Technical &
Pharma
Who we are?
*A+B shares July, 2013
Headquarter Copenhagen, Denmark
Founded 1925
Listed
Listen in 2000 at Copenhagen
exchange
Majority owner Novo A/S
Novozymes is the world leader in bioinnovation
Biopharma accounts for ~5-7% of our total
revenue
Pharmaceuticals & fine chemicals are one of the most
polluting industries
Industries Production Scale
(Tons per Year) E-factor
Oil Refining 106 - 108 < 0.1
Bulk Chemicals 104 - 106 < 1 - 5
Fine Chemicals Industry 102 - 104 5 - > 50
Pharmaceutical Industry 10 - 103 25 - >100
Source: R.A.Sheldon, Chem & Ind, 1992, 903 ; 1997, 12, IGCW 2011
Environmental impact of some of the chemical industries
3
A sustainable and greener footprint in chemical production is increasingly becoming a
global need…
There are existing and emerging solutions to counter pollution
Improving Manufacturing Sustainability: Enzymatic
Solutions can improve the overall sustainability profile
of pharmaceutical manufacturing
IN (kg)
Product
PROCESS
Raw Material 1
Raw Material 5
Raw Material 2
Raw Material 4
Raw Material 3
Out (kg)
LOSSES Waste Reject
By-products
Re-cycle
Re-use
Down-cycle
Re-sale
£
££
Pharmaceutical manufacture typically has > 100 kg raw
material consumption / kg product • Disposal costs
• Infrastructure costs
• Energy costs
Biocatalysis reactions adhere to green chemistry
principles
5
1. Enables new, sustainable
routes reducing waste
2. Enables more efficient routes
3. Generally low toxicity
4. Enables designing safer
molecules
5. Water as solvent or Class
II/Class III solvents
9. Catalytic with sustainable
and greener foot print
10. Flexibility in process design
and degradable
11. Real time analysis on
impact on pollution
possible
12. Minimal (negligible) risks
associated with reactions
8. Chemo, regio & stereo-
selective in nature
6. Performed at ambient
conditions 7. Renewable
Parameters of green chemistry principles in relation with biocatalysis
There are several benefits of using enzymes over
chemical reaction to produce APIs
General Advantages using Enzymes in API Manufacturing
Improved Productivity
− Higher Yields
− Shortened synthesis route
Milder reaction conditions
− Mostly ambient reaction condition
Greater Savings Potential
− Replaces costly chiral resolving agents
− Significant reduction in waste streams
Greater Selectivity
− High level of Stereo-, regio-, and
chemo-selectivity
Simplified work-streams
− Simplified processing and purification
− Fewer byproducts, reducing impurities
6
7
What are enzymes?
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guide
Enzymes are biological catalysts in the form of proteins having extraordinary specificity and catalytic power • Enzymes are present in all living cells, where they
catalyze chemical reactions and vital metabolic processes
• Enzymes reduce resource usage and increase the efficiency of the process
• Enzymes are not consumed in the process
• Enzymes operate under mild conditions
• Enzymes are fully biodegradable, and can replace chemicals in industrial production
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Enzymes enhance the rate of reaction by lowering the
activation energy for a chemical reaction……
8
E
Reactant
Product
Transition state
EA (-enzyme)
EA (+enzyme)
E+S
S + H2O
k1
k2
P1 + P2
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Lock & key Model- Enzymes are extremely selective in their
action
9
unique folded protein structure of enzymes
Active site of the enzyme hold the substrate by means of weak bonds or by hydrogen bonding
One or two amino acids in the active site like serine or histidine responsible for enzyme activity
Induced Fit Model
Active site of the enzyme changes its conformation to form enzyme substrate complex
Based on the reaction types, enzymes are grouped into
six main classes Enzyme Class EC No. Selected Reactions Novozymes Enzymes
Oxidoreductase 1
C=O and C=C reduction Reductive amination of C=O Oxidation of C-H,C=C, C-N
and C-O Cofactor reduction/oxidation
Transferase 2
Transfer of functional groups such as amino,Acyl,
phosphoryl, methyl, glycosyl, nitro & sulphur groups
Hydrolase 3
Hydrolysis of esters, amides, lactones, lactams, epoxides, nitriles & reverse reactions
Lyase (synthase)
4
Addition of small molecules to double bonds such as C=C, C=N and C=O
Isomerase 5
Isomerisations such as racemizations, epimerizations & rearrangement reactions
Ligases 6
Formation of complex compounds but enzymatically active only in presence of ATP as cofactor
10 Source:
Peroxidases (Catalases)
Glucose oxidases
Laccases
Fructosyltransferases
Glucosyltransferases
Amylases Cellulases
Lipases
Pectinases
Proteases Pullulanases
Phytases
Pectate lyases
Acetolactate decarboxylases
Glucose isomerases
No products at the moment
We have the most comprehensive lipase portfolio
Process Illustration 3
Use: For illustration of processes.
guide
CalA type of enzymes
candida antarctica lipase A
Allows branching on C-alpha and bulky side chains on the alcohol part
Key Applications
Kinetic Resolution of 2-
phenylbut-3-yn-2-ol
Resolution of 1-methyl-
1,2,3,4-tetrahydronapth-
alen-1-ol
CalB type of enzymes
candida antarctica lipase B
Allows larger groups on acid part and high specificity on alcohol part
Key Applications
Kinetic resolution of racemic 1,2,3,4-tetrahydroquoniline-2-acetate
Selective hydrolysis of hydroxydiethylcarboxylates
Resolution of Rivastigmineintermediate
Alcoholysis of glutaric anhydride
TLL type of enzymes
Thermomyces lanuginosus lipase
Allows larger groups on both alcohol and acid parts
Key Applications
Kinetic Resolution by
desymmetrization of
CNDE-key intermediate for
Pregabalin
11
Novozymes Immobilized Lipases……
guide
Novozym®435
Lipozyme®TL IM
TL enzyme adsorbed on
Silica Gel
Lipozyme ®RM IM
12
Macroporous Acrylic Resin
RM Enzyme adsorbed on
Macroporous Anionic Resin CALB enzyme adsorbed on
Alcalase Savinase
Some of the other important enzymes in Novozymes portfolio
are the proteases- Alcalase & Savinase
subtilisin based alkaline proteases
Available as liquid formulations
Alcalase 2.4LFG & Alcalase 2.5L
Key applications
Dynamic kinetic resolution of
protected Amino acids eg. DKR of
Benzylated Tyrosine
subtilisin based alkaline proteases
Availaible as Savinase 12T solid
granulate & liquid formulation
Savinase 16L
Key applications
Kinetic resolution of vince lactam-key
intermediate for Carbovir & Abacavir
13
Biocatalysis is a proven technology for some prominent API
synthesis
Pregabalin- Lipase from TL Source
Trandolapril- Novozym 435 (immobilised lipase)
Vince Lactam- Savinase (protease)
Posaconazole – Novozym 435 (immobilised lipase)
Darunavir- Novozyme 435/Lipozyme CALBL
Prostaglandin- Novozym 435 (immobilised lipase)
Case Studies of Application developed by Innovator using Novozymes Enzymes
14
Pregabalin Biocatalytic Route
Pregabalin Chemical synthesis Pregabalin Biocatalytic Route
15
Improvements due to replacing chemical process with chemoenzymatic reaction
Inefficient Resolution at rac.pregabalin
stage
Novozymes Lipase
Lipozyme TL 100 L
Flow Chart of Pregabalin Process……..
16
(R)-Diester (S)-Diester Water Enzyme
(R)-Diester (S)-Monoester Water Enzyme
(S)-Monoester Water Enzyme
Water Enzyme
Racemisation
Recycling
Key Advantages of Biocatalytic Route
Low protein Loading(0.8%)
Resolution at first stage-wrong isomer can be recycled
High throughput
All reactions conducted in water
E-factor improved from 86 to 17
Starting material reduction by 800 Mt
(cumulative)
Drastic reduction in solvent usage
Mandelic acid usage-500Mt eliminated
(Cumulative)
Energy usage reduced by 83%
Pregabalin
Biotreatment
23%
17
Inputs Chemical Route Kg
Chemoenzymatic Route
Kg
CNDE 6212 4798
Enzyme 0 574
S-Mandelic acid 1135 0
Raney Nickel 531 79.5
Solvents 50042 6230
Total 57920 11681.5
85%
88%
Reduction
Pregabalin Chemoenzymatic route used >5x less inputs than
Chemical Route
Raw Material Inputs for 1000kg API Output
Trandolapril Biocatalytic Route
Trandolapril Key Intermediate Synthesis Trandolapril Biocatalytic Route
Key Advantages of Biocatalytic Route:
18
Novozym 435 gives optimum performance in stereo selective synthesis of Trandolapril key
intermediate
Enzyme loading is low
Substrate concentration can be as high as 100g/L
Yield is high ~80-90% & ee> 98%
Enzyme can be recycled for approximately 5 times with out fresh loading
Reaction conditions i.e. pH & temperature is not very harsh
Reaction can be converted from batch to continuous process
O
O
OCH(OCH
3)3
CH3OH/H
2SO
4
O
O
O
O
CH3
CH3
O
O
O
OH
CH3
(R)
(S)
O
O
(R)
(S)
NH
HO
O
.HCl
Trandolapril
Key
Intermediate
O
O
OCH
3OH/H
2SO
4
O
O
O
O
CH3
CH3
O
O
O
OH
CH3
(R)
(S)
Novozym 435 pH-7.0-8.0; 30-35 C
Vince Lactam-Carbovir & Abacavir Key Intermediate
Biocatalytic Route
Carbovir & Abacavir Synthesis Vince Lactam Biocatalytic Route
Key Advantages of Biocatalytic Route:
Substrate concentration can be as high as 100g/L
Conversion is ~50% & ee of 1R,4S Vince lactam >99%
Reaction can be carried out in a mixture of solvent & phosphate buffer
Reaction is carried out under mild & ambient conditions 19
Savinase 12T is used on a commercial scale to produce Vince Lactam- Key Raw Material of
Carbovir & Abacavir
NH
ONHAcAcO
NH2OH
NH
OH N
N NH2
Cl
OH
N
N
NN
NH2
O
OH
N
N
NN
NH2
Cl
OH
N
N
NN
NH2
NH
Carbovir
Abacavir
NO
OOCH3
CH3
CH3
N
O
O
O
CH3
CH3
CH3
+HOOC
NH
O O
CH3CH3
CH3
Savinase 12T
Racemic Vince Lactam
4S
1R
1R
4S
1R,4S-Vince Lactam
(Required Isomer)
Vince Lactam
Key Raw Material
Posaconazole Key Intermediate Biocatalytic Route
Posaconazole Synthesis Posaconazole Intermediate Biocatalytic Route
Key Advantages of Biocatalytic Route:
Substrate concentration can be as high as 100g/L
Conversion is 70-80%
Reaction can be carried out in a non polar solvent like toluene
Immobilized enzyme can be recycled 20
Novozym 435 gives optimum performance in stereoselective synthesis of Posaconazole key
intermediate
F
F
OOTsN
N
N
+ OH N N N
N
N
O
CH3
CH3
OCH2Ph
1) NaOH
2) H2,Pd/C
F
F
ON
N
N O N N N
N
N
O
CH3
CH3
OCH2Ph
Posaconazole
F
F
OH
OH
CH2
F
F
OH
O
CH2
O CH3
CH3
+CH3
CH3
O
O
O
CH3
CH3
Novozym 435
F
F
OOTsN
N
N
Selective transesterification
Key Intermediate
Darunavir Key Intermediate Biocatalytic Route
Darunavir Synthesis
Key Advantages of Biocatalytic Route:
Substrate concentration can be as high as 100g/L
Reaction can be carried out using lipozyme CALBL or Novozym 435
Reaction can be carried out using water as a solvent
Reaction is carried out under mild & ambient conditions 21
Lipozyme CALBL is commercially used for stereoselective synthesis of key bicylcic intermediate
for Darunavir
O
O
O
O
ON
O
O +
N
CH3
CH3
NH2
OH
S
O
O
NH2
O
O
O
ON
CH3
CH3NH
OH
S
O
O
NH2
Key Bicyclic Intermediate
Darunavir Intermediate Biocatalytic Route
O O
OH
Acylation
O O
O
O
CH3
Lipozyme CALBL
or Novozym 435
O O
O
O
CH3H
H
+O O
OHH
H
hydrolysis
O O
OHH
H
NaH2PO
4 buffer,
40-45 C
Darunavir Key Intermediate
Latanoprost & Travoprost Biocatalytic Route
Latanoprost & Travoprost Synthesis
Key Advantages of Biocatalytic Route:
Biocatalytic reaction is carried out at high substrate concentrations.
Reaction yields are >90% & highly regioselective.
Reaction can be carried out using appropriate solvent or without any solvent
Reaction is carried out under mild & ambient conditions 22
Novozym 435 is used for the key regioselective esterification step
Latanoprost
Latonoprost & Travoprost Biocatalytic Route
OH
OH
COOH
Ph
OH
CH3
CH3
OH OH
OH
COO
Ph
OH
CH3
CH3
Latanoprost
Novozym 435
OH
OH
COOH
OPhCF 3
OH
CH3
CH3
OH OH
OH
COO
PhCF 3
OH
CH3
CH3
Travoprost
Novozym 435
Travoprost
OAc
OH
O
O
OH
OH
COO
Ph
OH
CH3
CH3
OH
OH
COO
PhCF 3
OH
CH3
CH3
Travoprost Latanoprost
Corey Lactone
Multiple
Steps
Future outlook of biocatalysis is very promising
Directed Evolution
Variant Selection or screening
Smarter Libraries of Enzymes
23
Advanced and Emerging Technologies
DNA technology & Protein engineering
Bioinformatics
Molecular Modelling studies-Docking of
substrate with proteins
Reaction engineering & process intensification
using biocatalysts
High throughput enzyme screening
Enzyme screening kits
First wave
living cells applied to useful chemical
transformations
Second Wave
Initial protein engineering techniques
extended range of enzymes to allow
synthesis of unusual synthetic
intermediates
Biocatalysis evolution so far and future outlook
So Far… the first and second wave The third wave: future outlook
CONTACT
NAME : DINESH NAIR
TITLE : REGIONAL BUSINESS MANAGER
EMAIL : [email protected]
WWW.BIOPHARMA.NOVOZYMES.COM
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